BIOMAT Database Logo BIOMAT Database Logo

An accurate two-phase approximate solution to an acute viral infection model. 2010

Amber M Smith, and Frederick R Adler, and Alan S Perelson
Department of Mathematics, University of Utah, Salt Lake City, UT 84112, USA. smith@math.utah.edu

During an acute viral infection, virus levels rise, reach a peak and then decline. Data and numerical solutions suggest the growth and decay phases are linear on a log scale. While viral dynamic models are typically nonlinear with analytical solutions difficult to obtain, the exponential nature of the solutions suggests approximations can be found. We derive a two-phase approximate solution to the target cell limited influenza model and illustrate its accuracy using data and previously established parameter values of six patients infected with influenza A. For one patient, the fall in virus concentration from its peak was not consistent with our predictions during the decay phase and an alternate approximation is derived. We find expressions for the rate and length of initial viral growth in terms of model parameters, the extent each parameter is involved in viral peaks, and the single parameter responsible for virus decay. We discuss applications of this analysis in antiviral treatments and in investigating host and virus heterogeneities.

UI MeSH Term Description Entries
D007251 Influenza, Human An acute viral infection in humans involving the respiratory tract. It is marked by inflammation of the NASAL MUCOSA; the PHARYNX; and conjunctiva, and by headache and severe, often generalized, myalgia. Grippe,Human Flu,Human Influenza,Influenza in Humans,Influenza,Flu, Human,Human Influenzas,Influenza in Human,Influenzas,Influenzas, Human
D007700 Kinetics The rate dynamics in chemical or physical systems.
D008954 Models, Biological Theoretical representations that simulate the behavior or activity of biological processes or diseases. For disease models in living animals, DISEASE MODELS, ANIMAL is available. Biological models include the use of mathematical equations, computers, and other electronic equipment. Biological Model,Biological Models,Model, Biological,Models, Biologic,Biologic Model,Biologic Models,Model, Biologic
D009716 Numerical Analysis, Computer-Assisted Computer-assisted study of methods for obtaining useful quantitative solutions to problems that have been expressed mathematically. Analysis, Computer-Assisted Numerical,Computer-Assisted Numerical Analysis,Analyses, Computer-Assisted Numerical,Analysis, Computer Assisted Numerical,Computer Assisted Numerical Analysis,Computer-Assisted Numerical Analyses,Numerical Analyses, Computer-Assisted,Numerical Analysis, Computer Assisted
D009980 Influenza A virus The type species of the genus ALPHAINFLUENZAVIRUS that causes influenza and other diseases in humans and animals. Antigenic variation occurs frequently between strains, allowing classification into subtypes and variants. Transmission is usually by aerosol (human and most non-aquatic hosts) or waterborne (ducks). Infected birds shed the virus in their saliva, nasal secretions, and feces. Alphainfluenzavirus influenzae,Avian Orthomyxovirus Type A,FLUAV,Fowl Plague Virus,Human Influenza A Virus,Influenza Virus Type A,Influenza Viruses Type A,Myxovirus influenzae-A hominis,Myxovirus influenzae-A suis,Myxovirus pestis galli,Orthomyxovirus Type A,Orthomyxovirus Type A, Avian,Orthomyxovirus Type A, Human,Orthomyxovirus Type A, Porcine,Pestis galli Myxovirus,Fowl Plague Viruses,Influenza A viruses,Myxovirus influenzae A hominis,Myxovirus influenzae A suis,Myxovirus, Pestis galli,Myxoviruses, Pestis galli,Pestis galli Myxoviruses,Plague Virus, Fowl,Virus, Fowl Plague
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D014779 Virus Replication The process of intracellular viral multiplication, consisting of the synthesis of PROTEINS; NUCLEIC ACIDS; and sometimes LIPIDS, and their assembly into a new infectious particle. Viral Replication,Replication, Viral,Replication, Virus,Replications, Viral,Replications, Virus,Viral Replications,Virus Replications

Related Publications

Amber M Smith, and Frederick R Adler, and Alan S Perelson
An approximate solution of the interferon-dependent viral kinetics model of influenza.
August 2020, Journal of theoretical biology,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
Approximate solution to the stochastic Kuramoto model.
November 2013, Physical review. E, Statistical, nonlinear, and soft matter physics,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
An approximate solution for a transient two-phase stirred tank bioreactor with nonlinear kinetics.
January 2005, Biotechnology progress,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
An approximate solution to the Lamm equation.
September 1979, Biophysical chemistry,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
Two-level system in a Gaussian field: An approximate solution.
February 1992, Physical review. A, Atomic, molecular, and optical physics,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
A simple method to obtain an approximate solution of the Free-Wilson model.
April 1978, Die Pharmazie,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
Acute phase protein response to viral infection and vaccination.
August 2019, Archives of biochemistry and biophysics,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
An approximate solution for two-dimensional groundwater infiltration in sewer systems.
January 2013, Water science and technology : a journal of the International Association on Water Pollution Research,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
Left ventricular ejection: model solution by collocation, an approximate analytical method.
May 1996, Computers in biology and medicine,
Amber M Smith, and Frederick R Adler, and Alan S Perelson
Diffusion-controlled reactions of enzymes. An approximate analytic solution of Chou's model.
September 1983, Biophysical chemistry,
Copied contents to your clipboard!